CN112717734A - Configuration structure of light oxygen clarification plant treatment module - Google Patents

Abstract

The invention discloses a configuration structure of a treatment module of light oxygen purification equipment, which comprises a box body and at least two rows of light oxygen lamp sets arranged in the box body along the advancing direction of waste gas flow; each light oxygen lamp in each row of light oxygen lamp groups is arranged back and forth along the width direction of the box body or is arranged up and down along the height direction of the box body, the centers of every four adjacent light oxygen lamps form a rectangular structure, the configuration structure of the processing module further comprises a first row guide plate group, a second row guide plate group and a third row guide plate group, wherein the first row guide plate group, the second row guide plate group and the third row guide plate group are arranged in the box body along the advancing direction of the waste gas flow, N is more than or equal to 2. Through increasing deflector group and will be listed as deflector group dislocation set at least, can increase waste gas air current walking route, improve waste gas air current and mix abundant degree to improve light oxygen clarification plant's treatment effeciency.

Description

Configuration structure of light oxygen clarification plant treatment module

Technical Field

The invention relates to the field of waste gas treatment of photo-oxidation purification equipment, in particular to a configuration structure of a treatment module of photo-oxidation purification equipment.

Background

The existing light oxygen purification equipment comprises a UV light oxygen lamp matrix and a photocatalyst plate matched with the UV light oxygen lamp matrix, wherein the UV light oxygen lamp has strong radiation and is mainly used for cracking organic substances in waste gas when the waste gas passes through and decomposing the organic substances into harmless carbon dioxide and water; the photocatalyst plate amplifies the light source effect and can improve the purification efficiency.

The purification combination configuration structure of the UV light oxygen lamp matrix and the photocatalyst plate matched with the UV light oxygen lamp matrix in the existing light oxygen purification equipment is usually simpler, and the measure for improving the waste gas treatment efficiency by fully mixing the waste gas flow is lacked. Some UV photo-oxidation devices are configured with similar measures, but have some defects, for example, chinese patent application No. 201720078917.2 discloses a high efficiency photo-oxidation catalytic device, the flow guide grid includes a grid and a plurality of flow guide vanes uniformly welded on the grid; the installation directions of the flow guide grids in the two adjacent groups of photo-oxidation catalytic units are opposite, and the design ensures that air flow is uniformly mixed, so that the photo-oxidation catalytic efficiency is improved; it has some problems: the central position of every adjacent distributed guide vane is a rectangular lattice structure, the positions of the guide vanes on every row and column are consistent, and the guide vanes are strung in the advancing direction of the exhaust gas flow, so that (1) when the width of the vanes is small, small local vortex gas flow is easy to appear, but because the periphery of the distributed vanes is a neutral gear, the resistance is small, most of the main exhaust gas flow is easy to escape and pass through the neutral gear between the rows and columns of the adjacent vanes, namely the neutral gear at the peripheral part outside the vane columns, and the effect is not ideal; (2) when the width of the blade is large, when the waste gas flows through, the vortex is stronger only at the position of the blade which is contacted with the blade firstly, and then the vortex effect is weakened step by step due to the layer blocking of the blade string at the same height behind the blade in the flowing direction of the gas flow, so that the effect is not ideal; (3) when the blade width is medium or equal, above-mentioned two problems also can the different degree exist, can not compromise, and partial air current directly escapes, passes through from the neutral gear outside the blade easily, and partial air current can be in the flow direction, through the layer upon layer barrier effect of blade cluster, and the vortex effect weakens step by step, and the effect is less than ideal.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides a configuration structure of a treatment module of a light oxygen purification device, which can increase the walking path of waste gas flow and improve the sufficient mixing degree of the waste gas flow by adding the guide plate groups and arranging at least two rows of guide plate groups in a staggered manner, thereby improving the treatment efficiency of the light oxygen purification device.

In order to achieve the purpose, the invention adopts the specific scheme that:

a configuration structure of a light oxygen purification equipment treatment module comprises a box body and at least two rows of light oxygen lamp groups arranged in the box body along the advancing direction of waste gas flow; each light oxygen lamp in each row of light oxygen lamp groups is arranged back and forth along the width direction of the box body or is arranged up and down along the height direction of the box body, the centers of every four adjacent light oxygen lamps form a rectangular structure, the configuration structure further comprises a first row guide plate group, a second row guide plate group and a third row guide plate group, the first row guide plate group, the second row guide plate group and the third row guide plate group are arranged in the box body along the advancing direction of the waste gas flow, N is more than or equal to 2, and at least.

Furthermore, at least two rows of guide plate groups arranged at an included angle of 30-150 degrees are arranged in the box body so that the airflow direction of flowing waste gas is turned, and the included angle between every two adjacent guide plates in each row of guide plate groups is any one of the completely consistent included angle, the partially inconsistent included angle and the completely inconsistent included angle.

Further, along the advancing direction of the exhaust gas flow, the distance between two adjacent guide plates in each row of guide plate groups is any one of equal distance, partially unequal distance and totally unequal distance.

Further, the axis of the guide plate in the guide plate group and the axis of the light oxygen lamp form an included angle of 0-180 degrees.

Furthermore, the shape of the guide plate is any one or more of a flat plate, an L-shaped plate, a curved plate, an arc-shaped plate, a curved folded plate or an irregular plate, and holes or lugs are arranged on the guide plate.

Furthermore, the box body also comprises an adjusting unit for adjusting the distance or the angle between two adjacent light oxygen lamps or between two adjacent guide plates, and each light oxygen lamp or each guide plate in the box body is directly fixed in the box body, is partially fixed on the adjusting unit and is completely fixed on the adjusting unit.

Furthermore, the waste gas treatment module also comprises a photocatalyst plate arranged in the box body along the advancing direction of the waste gas flow.

Further, the light oxygen purification equipment is vertical light oxygen purification equipment or horizontal light oxygen purification equipment.

Further, when the light oxygen purification equipment is vertical light oxygen purification equipment, the light oxygen lamps in each row of light oxygen lamp groups are arranged in front and at back along the width direction of the box body, and the included angle between the axis of each light oxygen lamp in each row of light oxygen lamp groups and the vertical direction is 0-45 degrees;

or;

when the light oxygen purification equipment is horizontal light oxygen purification equipment, all light oxygen lamps in all rows of light oxygen lamp groups are arranged up and down along the height direction of the box body, and the included angle between the axis of each light oxygen lamp in each row of light oxygen lamp groups and the horizontal direction is 0-45 degrees.

Has the advantages that:

1. the configuration structure of the invention is provided with guide plate groups for generating waste gas turbulent flow air mass, the guide plates in at least two guide plate groups are arranged in a staggered way, in the direction of waste gas flow, the waste gas flow can collide the front guide plate group from a relatively free dispersion state, the guide plates therein guide, remix, change the direction, flow out of the front guide plate group, and are in a free dispersion state again, and after continuously advancing and colliding the rear guide plate group staggered with the guide plates, the guide plates guide again, remix, change the direction, flow out of the guide plate groups, and are in a free dispersion state again, and continue advancing … … until the waste gas flow passes through the light oxygen purification equipment. Therefore, the walking path of the waste gas flow can be increased, and the mixing sufficiency of the waste gas flow is improved.

2. The waste gas treatment module can increase the walking path of the waste gas flow and improve the mixing degree of the waste gas flow, thereby improving the treatment efficiency of the light oxygen purification equipment.

3. The waste gas treatment module can also be provided with a photocatalyst plate, so that the light source effect can be amplified, and the purification efficiency can be improved.

4. The various changes contained in the invention can meet various requirements of users for improving the maximum effective ventilation quantity of the equipment and the treatment efficiency of the photo-oxygen equipment.

The present invention will be described in further detail with reference to the drawings and specific examples.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a top cross-sectional view of a prior art vertical photo-oxygen purification device exhaust treatment module.

Fig. 2 is a front sectional view of an exhaust gas treatment module of a horizontal photo-oxygen purification device in the prior art.

FIG. 3 is one of the top cross-sectional views of the waste gas treatment module of the vertical photo-oxygen purification device of the present invention.

FIG. 4 is a second sectional view of the top view of the waste gas treatment module of the vertical photo-oxygen purification device of the present invention.

FIG. 5 is a third sectional view of the top view of the waste gas treatment module of the vertical photo-oxygen purification device of the present invention.

FIG. 6 is one of the side views in longitudinal section of the exhaust gas treatment module of the vertical photo-oxygen purification device of the present invention.

FIG. 7 is a second vertical sectional side view of the exhaust gas treatment module of the vertical photo-oxygen purification device of the present invention.

FIG. 8 is a front sectional view of the waste gas treatment module of the horizontal photo-oxygen purification device of the present invention.

FIG. 9 is a second front sectional view of the waste gas treatment module of the horizontal photo-oxygen purification device of the present invention.

FIG. 10 is a third sectional view of the horizontal photo-oxygen purification device of the present invention.

FIG. 11 is a side view in longitudinal section of an exhaust gas treatment module of the horizontal photo-oxygen purification apparatus of the present invention.

FIG. 12 is a second longitudinal sectional side view of the waste gas treatment module of the horizontal photo-oxygen purification device of the present invention.

Graphic notation: 1. the device comprises a box body, 2, a light oxygen lamp, 3, a photocatalyst plate, 4, a guide plate, 5 and surrounding objects.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to specific embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As can be seen from fig. 1-2, the central positions of every adjacent four photo-oxygen lamps 2 (two of the two adjacent rows of photo-oxygen lamp sets) are in a rectangular lattice structure, and the configuration structures of the box 1 and the photo-oxygen lamps 2 are relatively common in the prior art.

Referring to fig. 3-12, the configuration structure of a light oxygen purification device processing module includes a box body 1, at least two rows of light oxygen lamp sets disposed in the box body 1 along the advancing direction of the exhaust gas flow; each light oxygen lamp 2 in each row of light oxygen lamp groups is arranged back and forth along the width direction of the box body 1 or arranged up and down along the height direction of the box body 1, the centers of every four adjacent light oxygen lamps 2 form a rectangular structure, the configuration structure further comprises a first row guide plate group, a second row guide plate group and a third row guide plate group, wherein the first row guide plate group, the second row guide plate group and the third row guide plate group are arranged in the box body 1 along the advancing direction of the waste gas flow, N is more than or equal to 2, and at.

When at least two rows of guide plate groups are staggered, the direction of the air flow can be turned, the guide plate groups can enable the air flow to enter from an equipment inlet, the air flow is led to an equipment outlet after at least two times of turning, and correspondingly, turning included angles exist in the air flow which is turned twice, and the range of the turning included angles is 30-150 degrees, so that at least two rows of guide plate groups with the included angles A of 30-150 degrees in the box body 1 can enable the direction of the air flow of the flowing waste gas to be turned (see fig. 4 and fig. 9).

Along the advancing direction of the exhaust gas flow, the included angle between two adjacent guide plates 4 in each row of guide plate groups is any one of all consistent, partially inconsistent and all inconsistent, please refer to fig. 4 and 9, the distance between two adjacent guide plates 4 in each row of guide plate groups can be equal or unequal, and the design can enable the photo-oxidation purification equipment to meet some special requirements, such as increasing or controlling the local turbulent flow degree of the gas flow.

The included angle B between the axis of the guide plate 4 in the guide plate group of the waste gas treatment module and the axis of the light oxygen lamp 2 adjacent to the guide plate is 0-180 degrees. If the space of the equipment site is limited, the guide plate 4 can be arranged perpendicular to the light oxygen lamp 2 (please refer to fig. 6 and 11), so that the air flow mixing effect can be increased or the cost can be reduced.

The shape of the guide plate 4 is any one or more of a flat plate, an L-shaped plate, a curved plate, an arc-shaped plate, a curved folded plate or an irregular plate, the guide plate can be a combined part or a discrete part, and the comprehensive effects of repeated collision flow guiding, free dispersion, re-collision flow guiding and mixing of airflow can be improved by limiting the shape of the guide plate 4. In addition, the guide plate 4 can be provided with holes or bumps, when the holes are arranged, a part of airflow directly escapes from the holes and passes through the holes, so that the resistance of the whole staggered guide plate group to the airflow can be reduced, and the beneficial effects of at least two staggered guide plate groups are retained; when the bump is provided, the turbulence degree can be increased.

It should be noted that, an adjusting unit for adjusting the distance or angle between two adjacent light oxygen lamps 2 or between two adjacent guide plates 4 may be disposed in the box body 1, and each light oxygen lamp 2 or each guide plate 4 in the box body 1 is any one of directly fixed on the equipment, partially fixed on the adjusting unit, and completely fixed on the adjusting unit. Wherein, the adjusting unit belongs to prior art, as long as can adjust interval and angle can. Therefore, after the equipment is manufactured or the equipment is in place on a production line, the distance and the angle between two adjacent light oxygen lamps 2 or two adjacent guide plates 4 can be adjusted to a reasonable range according to the specific conditions of a production field, and the best effect of treating the waste gas of the equipment is achieved.

The waste gas treatment module also comprises a photocatalyst plate 3 arranged in the box body 1 along the advancing direction of the waste gas flow.

The light oxygen lamp set, the flow guide plate set and the photocatalyst plate 3 in the waste gas treatment module are arranged along the advancing direction of the waste gas flow to form a member which at least comprises any combination of the light oxygen lamp set and the flow guide plate set, the arrangement sequence of the light oxygen lamp set, the flow guide plate set and the photocatalyst plate 3 along the advancing direction of the waste gas flow is any combination, wherein the combination can be the combination of the light oxygen lamp set and the flow guide plate set (at least two rows of the light oxygen lamp set and at least two rows of the flow guide plate set arranged in a staggered manner, such as fig. 3 and 8), or the combination of the light oxygen lamp set, the flow guide plate set and the photocatalyst plate 3 (at least two rows of the light oxygen set and at least two rows of the flow guide plate set in a staggered manner, such as fig. 4-5 and fig. 9-10), and the.

The optical oxygen purification equipment is vertical optical oxygen purification equipment or horizontal optical oxygen purification equipment.

In detail, when the light oxygen purification device is a vertical light oxygen purification device, please refer to fig. 3-5, each light oxygen lamp 2 in each row of light oxygen lamp group is arranged back and forth along the width direction of the box body 1, and an included angle C between the axis of each light oxygen lamp 2 in each row of light oxygen lamp group and the vertical direction is 0-45 °, so that the adaptability of the device to the site is increased, for example, sometimes the device box body can be obliquely installed to avoid the surrounding objects 5 when the installation site is limited.

In detail, when the light oxygen purification device is a horizontal light oxygen purification device (please refer to fig. 8-10), each light oxygen lamp 2 in each row of light oxygen lamp set is vertically arranged along the height direction of the box body 1, and an included angle D between the axis of each light oxygen lamp 2 in each row of light oxygen lamp set and the horizontal direction is 0-45 °.

According to the invention, by adding the guide plate group, the traveling path of the waste gas flow can be increased, and the sufficient mixing degree of the waste gas flow is improved, so that the treatment efficiency of the photo-oxidation purification equipment is improved; the equipment can be adjusted to the best effect of waste gas treatment according to the specific conditions of the production field after the equipment is manufactured or the equipment is in place on the production line; the structural form of the equipment can be flexibly configured according to actual needs, and a more reasonable waste gas treatment mode is realized or the special requirements of users are met.

The foregoing is merely a preferred embodiment of the invention and is not to be construed as limiting the invention in any way. All equivalent changes or modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (9)

1. A configuration structure of a light oxygen purification equipment treatment module comprises a box body and at least two rows of light oxygen lamp groups arranged in the box body along the advancing direction of waste gas flow; each light oxygen lamp in each row of light oxygen lamp group sets up around the width direction of box or all sets up from top to bottom along the direction of height of box, and the center of every adjacent four light oxygen lamps constitutes rectangular structure, its characterized in that: the configuration structure of the treatment module further comprises first to Nth guide plate groups which are arranged in the box body along the advancing direction of the waste gas flow, wherein N is more than or equal to 2, and at least two guide plate groups are arranged in a staggered mode.

2. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: at least two rows of guide plate groups arranged at an included angle of 30-150 degrees are arranged in the box body so that the airflow direction of flowing waste gas is turned, and the included angle between every two adjacent guide plates in each row of guide plate group is any one of all consistent, part inconsistent and all inconsistent.

3. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: and along the advancing direction of the waste gas flow, the distance between two adjacent guide plates in each row of guide plate groups is any one of equal distance, partial unequal distance and total unequal distance.

4. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: the included angle between the axis of the guide plate in the guide plate group and the axis of the light oxygen lamp is 0-180 degrees.

5. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: the shape of the guide plate is any one or more of a flat plate, an L-shaped plate, a curved plate, an arc, a curved folded plate or an irregular plate, and holes or lugs are arranged on the guide plate.

6. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: the box body also comprises an adjusting unit for adjusting the distance or the angle between two adjacent light oxygen lamps or between two adjacent guide plates, and each light oxygen lamp or each guide plate in the box body is directly fixed in the box body, is partially fixed on the adjusting unit and is completely fixed on the adjusting unit.

7. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: the waste gas treatment module also comprises a photocatalyst plate arranged in the box body along the advancing direction of the waste gas flow.

8. The configuration structure of a light oxygen purification device treatment module according to claim 1, wherein: the light oxygen purification equipment is vertical light oxygen purification equipment or horizontal light oxygen purification equipment.

9. The configuration structure of a light oxygen purification device treatment module according to claim 8, wherein: when the photo-oxygen purification equipment is vertical photo-oxygen purification equipment, the photo-oxygen lamps in each row of photo-oxygen lamp groups are arranged in front and at back along the width direction of the box body, and the included angle between the axis of each photo-oxygen lamp in each row of photo-oxygen lamp groups and the vertical direction is 0-45 degrees;

or;

when the light oxygen purification equipment is horizontal light oxygen purification equipment, all light oxygen lamps in all rows of light oxygen lamp groups are arranged up and down along the height direction of the box body, and the included angle between the axis of each light oxygen lamp in each row of light oxygen lamp groups and the horizontal direction is 0-45 degrees.

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